JP4927129B2 - Radial gas expander - Google Patents

Abstract

Provided is a uni-axial multi-stage radial gas expander which has a high degree of reliability and which can sufficiently cope with the conditions of a high pressure and a high pressure ratio. Two or more radial gas expander sections (11A, 11B) formed of two-or-more-stage impeller vanes (14a to 14h) arranged between bearings (21a, 21b) on a rotor shaft (13) consisting of a single shaft are housed in a signal casing (10).

Description

  The present invention relates to a radial gas expander (radial flow gas expander) in which impeller rotor blades are arranged in multiple stages on a single axis.

  The purpose of the gas expander is to absorb the high-pressure gas discharged from the plant side, expand it, and convert the pressure energy of the gas into velocity energy (mechanical energy) to recover the power and reduce the power of the drive motor, etc. It is well known in Patent Document 1 and the like.

  In this gas expander, when it is necessary to provide gas expanders in multiple stages in order to cover (absorb) a high pressure ratio or to improve performance, for example, a geared type (acceleration gear type) as shown in FIG. A radial gas expander is conceivable (see Patent Document 2).

  According to this, the expander wheel shaft 102 is supported by the gear casing 100 via the bearing 101 </ b> A, and a plurality of expander pinion shafts (impeller shafts) 103 parallel to the expander wheel shaft 102 are connected to the gear casing 100. Are supported by bearings 101B. Expander impellers (impeller blades) 104 of high pressure stages A, B, C, and D are arranged at both ends of one expander pinion shaft 103 shown in the figure, and both ends of the other expander pinion shaft 103 are arranged. The expander impeller (impeller rotor blades) 104 in the low pressure stage of E and F are arranged in.

  In each stage, high-temperature and high-pressure gas discharged from the plant side is made up of an inflow casing 105 configured as a spiral casing and guide vanes (nozzle blades) 107 provided in the disc annular space 106. The air is drawn into the expander impeller 104, expands, and is discharged from the outlet conical diffuser 108. Further, the power recovered by sucking and expanding the gas is transmitted to the expander wheel shaft 102 through the gear train, and the power of a drive motor (not shown) is reduced. In the one expander pinion shaft 103, the gas emitted from the first stage expander impeller 104 is sucked into the second stage expander impeller 104 through a return ring (return bend) 109. Gas suction and expansion are repeated over two stages.

Japanese Patent No. 3457828 (2nd page, FIG. 6) JP-A-6-193585 (page 7, FIG. 24) Japanese Patent Laid-Open No. 3-168304 (first page, FIG. 1)

  However, in the geared type radial gas expander as shown in FIG. 4, the number of expander pinion shafts (impeller shafts) 103 is increased as the number of stages increases, and accordingly, a plurality of high pressure seals and high pressure casings are provided. Necessary.

  For this reason, there are many uneasy factors regarding machine reliability such as gas leakage and shaft vibration under high pressure and high pressure ratio conditions, and there is a problem that it is difficult to ensure reliability.

  In addition, the radial gas expander shown in FIG. 4 is provided with high-pressure two-stage radial gas expanders A, B and C, D at both ends of one expander pinion shaft 103. Since the so-called cantilever type is supported on the free end side of the expander pinion shaft 103 located outside the bearing 101B, there is a problem in that shaft vibration increases, and it is impossible to increase the number of stages in two stages. At the same time, there is a drawback that it is impossible to cope under high pressure and high pressure ratio conditions.

  Therefore, an object of the present invention is to provide a highly reliable single-shaft multistage radial gas expander that can sufficiently cope with conditions of high pressure and high pressure ratio.

  Note that Patent Document 3 discloses a power generation device in which gas expanders are arranged in multiple stages on a rotor, but this is an axial gas expander (axial flow gas expander), and a radial gas expander is a pressure generator. The level is different and it cannot be applied under the conditions of high pressure and high pressure ratio.

A radial gas expander according to the present invention for achieving such an object,
A radial gas expander section in which two or more stages of impeller blades are arranged between bearings on a single rotor shaft is incorporated in a single casing.
The radial gas expander section is provided with a plurality of axially connected diaphragms having return bends connecting between the stages, and a gas flow corresponding to the profile of the impeller blades is generated in the return bend. A nozzle vane and a return vane for making the gas flow to the next stage inlet into an efficient gas flow are respectively interposed,
The radial gas expander section is provided to be separated by a partition plate over two or more sections, and a gas inlet communicating with the suction port of the single casing and a gas outlet communicating with the discharge port for each section. It is characterized by having.

Also,
The radial gas expander section is provided with two or more sections so that the gas flow direction is divided into two in the opposite direction of the rotor shaft.

  According to the radial gas expander according to the present invention, since a single shaft is sufficient even in multiple stages, the number of high-pressure seals and high-pressure casings can be minimized as compared with a conventional geared-type radial gas expander or the like. In addition, since a radial gas expander section is provided between the bearings on a single shaft, it is easier to consider shaft alignment compared to multiple shafts, and shaft vibration design compared to a cantilever radial gas expander section Is also easy. In addition, since a single casing is sufficient, it can be easily supported at the axial center line position.

  As a result, anxiety factors regarding machine reliability such as gas leakage and shaft vibration under conditions of high pressure and high pressure ratio are eliminated, and a more reliable uniaxial multistage radial gas expander is realized.

1 is a front sectional view of a uniaxial multi-stage radial gas expander showing an embodiment of the present invention. It is A arrow directional view in the balloon of FIG. It is a B arrow view in the balloon of FIG. It is a front sectional view of a conventional geared type radial gas expander.

  Hereinafter, a radial gas expander according to the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 is a front sectional view of a uniaxial multi-stage radial gas expander showing an embodiment of the present invention, FIG. 2 is a view as viewed from an arrow A in FIG. 1, and FIG. 3 is a view as viewed from an arrow B in FIG.

  As shown in FIG. 1, two radial gas expander sections 11 </ b> A and 11 </ b> B whose gas flow directions are opposite to the rotor axial direction are built in a single barrel-shaped (tubular) casing 10. The trunk casing 10 has a suction port 10a communicating with a gas inlet (port) 12a of one radial gas expander section 11A and a suction port communicating with a gas inlet (port) 12b of the other radial gas expander section 11B. A port 10b is formed, and a discharge port 10c communicating with the gas outlet (port) 12c of one radial gas expander section 11A and a discharge port communicating with the gas outlet (port) 12d of the other radial gas expander section 11B 10b is formed.

  The two radial gas expander sections 11A and 11B are composed of a plurality of (11 in the illustrated example) diaphragms (disc-shaped annular partition plates) 15 and 16a, which are connected in a longitudinal direction of the trunk casing 10 so as to be removable. 16b, 17a, 17b, 18a, 18b, 19a, 19b, 20a, 20b, and a central diaphragm 15 and five diaphragms 16a, 17a, 18a, 19a, 20a on one side (left side in the figure) One radial gas expander section 11A, the central diaphragm 15 and the other diaphragms 16b, 17b, 18b, 19b, and 20b on the other side (right side in the figure) are the other radial gas expander section 11B. It is configured.

  That is, the rotor shaft 13 consisting of a single axis passes through the center of each of the diaphragms 15, 16a, 16b, 17a, 17b, 18a, 18b, 19a, 19b, 20a, and 20b. The two diaphragms 20a and 20b, which are also end plates in the radial gas expander sections 11A and 11B, are rotatably supported via bearings 21a and 21b. Also, dry gas seals 22a and 22b are accommodated on the inner peripheral portions of the diaphragms 20a and 20b located inside the bearings 21a and 21b.

  On the rotor shaft 13, a plurality of stages (four stages in the illustrated example) of impeller rotor blades 14a to 14d for one radial gas expander section 11A and a plurality of stages for the other radial gas expander section 11B. Impeller rotor blades 14e to 14h (four stages in the illustrated example) are arranged with their directions opposite to each other.

  Gas inlets 12a and 12b communicating with the suction ports 10a and 10b are formed between the contact surfaces of the central diaphragm 15 and the diaphragms 16a and 16b located on both sides thereof. Gas outlets 12c and 12d communicating with the aforementioned discharge ports 10c and 10d are formed between the contact surfaces of the two diaphragms 20a and 20b and the diaphragms 19a and 19b adjacent to the two diaphragms 20a and 20b.

  The intermediate diaphragms 17a, 18a, 19a and 17b, 18b, 19b in each radial gas expander section 11A, 11B have a return bend (U-shaped cross section connecting the steps as shown in FIGS. 2 and 3). Intermediate flow paths) 23 are formed, and a plurality of (17 in the illustrated example) nozzle blades 24 that generate gas flows corresponding to the profiles of the impeller blades 14b to 14d and 14f to 14h are formed in these return bends 23. And a plurality of return vanes 24 (17 in the illustrated example) for making the gas flow to the next stage inlet into an efficient gas flow are respectively interposed. Of course, the nozzle blades 24 that generate gas flows corresponding to the profiles of the impeller rotor blades 14a and 14e are also interposed in the gas inlets 12a and 12b.

  With this radial gas expander, when the high-temperature and high-pressure gas discharged from the plant side is supplied to the suction ports 10a and 10b of the single casing 10, for example, each radial gas expander section is configured as described above. In 11A and 11B, drive motors that drive the rotor shaft 13 by repeatedly sucking and expanding gas through four stages by impeller rotor blades 14a to 14d and 14e to 14h each having four stages to recover power. Reduce the power of. In the present embodiment, since the two radial gas expander sections 11A and 11B are provided, a power reduction effect corresponding to the sum of the radial gas expander sections 11A and 11B can be obtained.

  In the present embodiment, the rotor shaft 13 may be a single shaft even in a multi-stage (strictly 8 stages). Therefore, the dry gas seals 22a and 22b have a minimum number of 2 as compared with a conventional geared type radial gas expander or the like. In addition to a single piece, the casing 10 may be a single casing that can be easily supported.

  In addition, since two radial gas expander sections 11A and 11B are provided between the bearings 22a and 22b on the single rotor shaft 13, it is easier to consider the shaft alignment than a plurality of shafts, and cantilever type Compared with the radial gas expander section, the design of shaft vibration is also easier.

  The two radial gas expander sections 11A and 11B include a plurality of diaphragm diaphragms 15, 16a, 16b, 17a, 17b, 18a, 18b, 19a, 19b, 20a, in which return vents 23 and the like connecting the stages are formed. Since a plurality of 20b are connected in the axial direction, they can be firmly and easily assembled in the single casing 10.

  In addition, since the gas flow directions of the two radial gas expander sections 11A and 11B are opposite to each other, the pressures of the two radial gas expander sections 11A and 11B can be offset, and the thrust acting on the rotor shaft 13 is well balanced. .

  The two radial gas expander sections 11A and 11B include gas inlets 12a and 12b communicating with the suction ports 10a and 10b of the single casing 10 and gas outlets 12c and 12d communicating with the discharge ports 10c and 10d for each section. It is easy to change the number of sections.

  As a result, anxiety factors regarding machine reliability such as gas leakage and shaft vibration under conditions of high pressure and high pressure ratio are eliminated, and a more reliable uniaxial multistage radial gas expander is realized.

  It should be noted that the present invention is not limited to the above-described embodiments, and various modifications such as changing the number of sections of the radial gas expander section and changing the number of stages of the radial gas expander are possible without departing from the scope of the present invention. Nor.

  The radial gas expander according to the present invention is applied to a plant or the like that sucks high-pressure gas discharged from the plant side, expands it, recovers power, and uses the exhaust gas that has become low temperature by expansion as a reheat cooler. be able to.

DESCRIPTION OF SYMBOLS 10 Single casing 10a, 10b Suction port 10c, 10d Discharge port 11A, 11B Radial gas expander section 12a, 12b Gas inlet 13 Rotor shaft 14a-14h Impeller rotor blade 15 Center diaphragm 16a, 16b, 17a, 17b, 18a, 18b, 19a, 19b Middle diaphragm 20a, 20b Diaphragm which is also an end plate 21a, 21b Bearing 22a, 22b Dry gas seal 23 Return bend (intermediate flow path)
24 Nozzle blades 25 Return vanes

Claims (2)

A radial gas expander section in which two or more stages of impeller blades are arranged between bearings on a single rotor shaft is incorporated in a single casing.
The radial gas expander section is provided with a plurality of axially connected diaphragms having return bends connecting between the stages, and a gas flow corresponding to the profile of the impeller blades is generated in the return bend. A nozzle vane and a return vane for making the gas flow to the next stage inlet into an efficient gas flow are respectively interposed,
The radial gas expander section is provided to be separated by a partition plate over two or more sections, and a gas inlet communicating with the suction port of the single casing and a gas outlet communicating with the discharge port for each section. A radial gas expander characterized by comprising:   2. The radial gas expander according to claim 1, wherein the radial gas expander section is provided with two or more sections so that a gas flow direction is divided into two opposite directions of the rotor shaft.

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